DE3126691A1 - RECEIVING ANTENNA - Google Patents

Description

DR.-ING. ULRICH GARLIC ..:. PATENT Attorney - 4 - 'β frankfurt / main 1, den

KUHHORNSHOWEG 10 POSTSCHECK ACCOUNT PRANKFURT / M. 34 25 605

riRESDNER ΠΑΝΚ. FRANKFURT / M. 2300308 TRlEFO (M 561078 t

TELEGRAM KNOPAT X

TELEX 4 1187 / KNOPA Π

TDK ELECTRONICS CO., LTD. Tokyo (Japan)

Receiving antenna

The invention relates to a receiving antenna with a vertical ferrite rod which has a circular cross-section and is provided with an oscillating circuit coil and an output coil, the oscillating circuit coil having an adjustable Capacitor is connected, which together with the resonant circuit coil forms the resonant circuit, and the output coil with output connections connected is.

The antenna is particularly suitable for receiving radio broadcasts with frequency modulation in the range from 76 to 90 MHz.

Fig. 1A shows a known ferrite antenna of this type with a vertical ferrite rod 1. With 2, a resonant circuit is designated. It consists of one wound around the ferrite rod 1 Coil 3 and a variable capacitor 4. Furthermore, an output coil 5 is wound around the ferrite rod 1. Ferrite antennas are often used because they emit a high output voltage due to the high permeability of the ferrite rod. The resonance frequency of the oscillating circuit 2 is adjusted to the desired reception frequency by means of the variable capacitor 4 tunable. The antenna output voltage is provided by the output coil 5 removed via output connections 6.

The antenna gain G of the antenna according to FIG. 1A is ^G « ¹ i5 f \ Q _e

Here / u _{e means} the effective permeability of the ferrite rod, Q _e the effective quality of the window rod, S the cross-sectional area of the ferrite rod, L _f the length of the ferrite rod and ^ U the wavelength in empty space. The antenna gain G is therefore proportional _{to the quantities / U 6} , Q _ft , S and L _f.

FIG. 1B shows the dependence of the antenna gain G on the length L _f and the diameter 0 of the ferrite antenna according to FIG. 1A, the sizes M _e and Q _{ft being} predetermined. As FIG. 1B shows, the antenna gain G increases with the diameter 0 and the length L.

However, if the ferrite rod length exceeds a predetermined value, the antenna gain G decreases because of the losses in the ferrite rod, and furthermore the resonance frequency of the antenna lies due to their self-inductance and stray capacitance in the VHF range. Since a ferrite antenna is not direction-dependent in the horizontal plane, it receives due to multiple reflections electromagnetic waves, e.g. on buildings and / or other reflectors, an echo.

Another known antenna for the VHF and / or UHF range is a dipole antenna, the length of which is equal to half the wavelength. However, such a dipole antenna has the disadvantage that it is very bulky because of its size.

The invention is based on the object of a receiving antenna Specify the generic type for the VHF and / or UHF range is suitable, has a high antenna gain and small dimensions.

According to the invention, this object is achieved in that the Antenna has a housing that extends from the top of the housing two substantially right-angled wings of a horizontal first antenna part in mutually opposite directions

extend away that the wings form a folded elongate conductor with a plurality of first sections of length D in parallel to the direction of the wings and several second sections of length H perpendicular to the direction of the first sections, that the outer ends of the folded elongated conductor are free in the wings, that the ferrite rod is arranged in the housing is that the ferrite rod has a coupling coil with the inner ends of the folded elongated conductor in the wings is connected that the first antenna part with the two Wings in the horizontal direction have a total length L in the range of about 350 mm to 700 mm, that the length of the first Sections about 6 mm to 12 mm and the length of the second sections about 40 mm to 150 mm and that the ferrite rod has a diameter of about 10 mm to 30 mm and a length of about 50 mm to 150 mm.

The output coil is preferably displaceable along the ferrite rod, to adjust the output resistance of the receiving antenna.

The invention and its developments are described in more detail below with reference to the drawings. Show it:

1A shows the structure of a known ferrite rod antenna,

1B shows the dependence of the antenna gain of the ferrite rod antenna according to Fig. 1A of their dimensions,

2 shows the basic structure of an antenna according to the invention,

3 shows a further exemplary embodiment of an antenna according to the invention,

FIG. 4A shows the top view of the antenna according to FIG. 2,

Fig. 4B shows the cross section A-A according to Fig. 4A,

FIGS. 5A, 5B and 5C show in more detail the structure of the lower part of the antenna according to FIGS. 4A and 4B,

Figures 6A, 6B and 6C show an alternative construction of the lower part of the antenna according to Figures 4A and 4B;

7 shows the dependence of the output resistance of the invention Antenna on the frequency,

8 shows the dependence of the antenna gain on the dimensions of the ferrite rod of the antenna according to FIG. 2,

9A and 9B show the antenna gain as a function of Dimensions of the folded horizontal antenna part,

10 shows the antenna gain as a function of the invention Antenna compared to the antenna gain of known antennas and

11 shows the radiation diagram of the antenna according to the invention.

2 and 3 show circuit diagrams designed according to the invention Antennas and FIGS. 4A and 4B show the structure of the antenna according to FIG. namely Fig. 4A in plan view and Fig. 4B in cross section A-A of Figure 4A. The receiving antenna has an elongated first antenna part 10, which is oriented horizontally, and one Ferrite rod 13, which is placed vertically. Around the upper part of the ferrite rod 13, a coil 12 is wound, and from the Ferrite rod 13, the coil 12, an oscillating circuit 14 and one Output coil 15 existing arrangement forms a second antenna part. The first antenna part 10 has a conductor that folds or bent back and forth as shown in the figure. In the embodiment according to FIGS. 2, 4A and 4B, the folded conductor lies in a vertical plane. The horizontal

312669 TV

Component of the folded conductor, which extends in the longitudinal direction of the first part 10, is called the first portion 51a and the to this perpendicular component referred to as second section 51b. The outer end 11 of the folded conductor is free or open, as shown in the figure. This one horizontally folded ladder is divided into two parts or wings 10a and 10b (see Fig. 4A). The ends 12a and 12b of the coil 12 are each connected to one of the inner ends of these halves or wings 10a and 10b.

Another coil 14a is wound around the central part of the ferrite rod 13 and connected to a variable capacitor 14b. The coil 14a and the capacitor 14b form a tunable one Resonance circuit. Around the lower part of the ferrite rod 13 is another coil 15 is wound, which is connected to output connections 17 of the antenna via a symmetrizing transformer 16 for adaptation of the line resistance is coupled. This balancing transformer is not shown in Figs. 4A and 4B. The coil forms the output coil.

FIG. 3 shows the circuit diagram of a further receiving antenna according to the invention. What is special about the antenna according to FIG. 3 is that the first antenna part 10 lies in a horizontal plane, while the first antenna part 10 according to Fig. 2 in a vertical plane.

The antenna gain of the antenna according to FIG. 3 is essentially the same as that of the antenna according to FIG. 2.

The mechanical structure of the antenna according to the invention is described below with reference to FIGS. 4A and 4B. The antenna has a Housing 20 with an upper cover 21, a lower cover 22 and side walls 23a, 23b. A circular disc 24 engages into the top cover 21 so that the disk 24 is rotatable about its own axis. Under the disk 24 is a first upper bobbin 25 made of dielectric material attached.

The coupling coil 12 is wound around this first bobbin 25.

The two wings 10a and 10b of the first antenna part 10 each have a thin rectangular dielectric plate 30. Every At one end of the plate 50 has a small projection 50a or 50b by means of which it is attached to the disk 24. Of the folded conductor is embedded in the dielectric plate 50 as shown by the dashed lines in the figures is. This conductor has a predetermined period with the horizontal portions 51a of length D and the vertical portions 51b of length H. One end of each wing conductor is electrically connected to the associated end of the coil 12 through the disk 24 connected while the other end 11 of the conductor is exposed. The first antenna part 10 is therefore together with the first upper one Winding body 25 and the coil 12 around the axis of the winding body 25 around. The first antenna part is opened by rotation aligned with the direction of the electromagnetic wave to be received.

The second lower dielectric bobbin 26 is on the lower Cover 22 of the housing 20 attached so that the two winding bodies 25 and 26 are coaxial. Between the two bobbins 25 and 26 there is a short air gap. The underside of the ferrite rod passed through the two winding bodies 25 and 26 13 is adhered to the lower cover 22.

The resonant circuit coil 14a is wound around the second bobbin 26 and connected to the variable capacitor 14b Lines connected. The variable capacitor 14b is on a vertical plate 30 attached to the bottom cover 22 stands. The capacitor 14b is connected with the aid of a rotary knob 40 adjustable, which is outside the housing 10.

A third winding body 27 is located on the second winding body 26 axially displaceable. On this third winding body 27

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the output coil 15 is arranged. It is with the output connections 17 connected to the side wall of the housing 10. If a balun transformer is provided, it can be inside or be arranged outside the housing electrically between the output coil 15 and the output terminals 17. In one end of the Third winding body 27 engages a screw 28, which also engages in a projection 29 on the base plate 22. By Turning the screw 28 .by means of a screwdriver, the position of the third winding body 27 on the second winding body finely adjusted. The position of the third bobbin 27 and the output coil 15 determine the output resistance of the antenna.

The bobbins 25 and 26 each have one on their outside circumferential groove in which one of the coils 14a and 15 is arranged is.

FIGS. 5A, 5B and 5C show the structure of the third bobbin 27 of the embodiment of FIGS. 4A and 4B in more detail. As FIGS. 5A to 5C show, the second winding body 26 has a vertical groove 26A in the outside and the third bobbin 27 an inner projection 27d, which in the vertical straight groove 26 engages. The engagement of the projection 27d in the groove 26a prevents rotation of the third winding body 27 and / or the output coil 15. The third winding body 27 has a circular circumferential groove in which the output coil 15 is arranged, and the connecting lines from the output coil 15 to the output terminals 17 are through two adjacent Slots 27e passed through. Sufficient for the VHF / UHF range an output coil with only one turn. The third winding body 27 also has an outer projection 27b with a threaded hole 27c. The screw 28 for adjusting the position of the third winding body 27 engages in this threaded bore 27c. if the position of the third winding body 27 is set, the screw 28 is secured by means of a lock nut 28a.

Figures 6A, 6B and 6C represent the lower part of another Exemplary embodiment. The special feature of this embodiment is that the second winding body is omitted and the winding body 27 arranged directly on the ferrite rod 13 is. In this case, a vertical straight groove may be formed in the ferrite rod 13.

Fig. 7 shows the dependence of the output impedance (the ripple factor or standing wave ratio VSWR) from the reception frequency f with the positions (a), (b) and (c) of the coil former 27 as a parameter (see, for example, FIG. 6B). As FIG. 7 shows, the output impedance of the antenna depends on the position of the Spool 27 or the output coil 15 and the frequency. Since the output impedance should be matched (which means that VSWR-1), the position of the output coil is set for each receiving frequency so that the value of VSWR becomes a minimum.

During operation, the antenna is arranged so that the Ferrite rod 13 vertically and the first antenna part 10 horizontally is aligned. The horizontal first antenna part 10 is rotated so that the wings 10a and 10b are perpendicular to the direction of propagation of the electromagnetic waves to the maximum To achieve antenna gain. Then the adjustable resistor is set so that the resonance frequency of the resonant circuit with matches the reception frequency. Then the location of the third The winding former or the output coil is adjusted so that the output impedance results in the minimum standing wave ratio VSWR. These three measures can be carried out in such a way that the reception amplitude becomes a maximum. However, the attitude is bearing the output coil does not contribute much to the antenna gain. The position of the output coil can therefore remain fixed, after it has been set to a position suitable for the center frequency of the receiving frequency range.

Characteristic curves of the antenna according to the invention and some dimensioning variables are described below with reference to FIGS. 8 to 11.

For the practical application of the antenna, it is preferable that the ferrite rod having a diameter of 0 «now 6-35 and a length L _f" 25-200 mm 13 and the output impedance is 300 ohms, which is matched to the input impedance of a balun transformer. If the size of the ferrite rod is decreased, the antenna gain and output impedance will also decrease, and if the size of the ferrite rod is increased, the output impedance will increase and the antenna gain will decrease due to the mismatching of the impedance.

8 shows the dependence of the antenna gain G of the antenna according to FIG. 2 on the length L _{f of} the ferrite rod with the diameter 0 of the ferrite rod as a parameter, the length L- in mm on the horizontal axis and the antenna gain G on the vertical axis are plotted and the test frequency is 83 MHz. As FIG. 8 shows, in order to achieve a high antenna gain, the diameter 0 should be in the range from 8 mm to 30 mm and the length Lx. are in the range from 50 mm to 200 mm. The maximum antenna gain is obtained in these areas if the diameter is around 20 mm and the length L- is around 75 mm. If the dimensions are in the range mentioned, the measured output impedance of the ferrite antenna is in the range of about 100 ohms to 200 ohms and the output impedance of the first antenna part is in the range of about 30 ohms to 150 ohms. If the dimensions are chosen so that the maximum antenna gain results (0 «20 mm, L _f » 75 mm), the measured output impedance of the second ferrite antenna part is 150 ohms and the measured output impedance of the first horizontal antenna part is 80 ohms. These values of the output impedance do not contain the influence of the coupling coil 12 according to FIG. 2, in other words, the first antenna part is separated from the second ferrite antenna in order to measure the output impedance of the two parts separately. In practice, the first horizontal part and the second vertical ferrite rod part are coupled by the coupling coil 12 so that the preferred output impedance of the combined antennas of the first horizontal part and the vertical ferrite rod part is 300 ohms

amounts to.

9A shows the gain of the antenna according to FIG. 2, if the length D of the first sections 21a and the length H of the second sections 51b (see Fig. 2) are adjusted and the diameter 0 and the length L ^ of the ferrite rod are selected so that the antenna gain of the ferrite rod is maximum (0-20 mm, L _f «75 mm), where the antenna gain G is plotted on the vertical axis and the length H of the second sections 51b is plotted on the horizontal axis and the length D of the first sections 51a is selected as a parameter. As FIG. 9A shows, a high antenna gain G results when the length D is in the range from 6 mm to 12 mm and the length H in the range from 40 ram to 150 mm. And the maximum antenna gain results when the length D is approximately equal to 8 mm and the length H is approximately equal to 60 mm.

FIG. 9B shows the measured antenna gain of the antenna according to FIG. 2 when the overall horizontal length L of the first antenna part 10 (see FIG. 2) is changed, the antenna gain G is plotted on the vertical axis and the length L on the horizontal axis and the length D of the first sections 51a of the folded conductor as a parameter, whereas the length H is chosen to be constant equal to 60 mm. As shown in Fig. 9B, a high antenna gain when the length D of the first sections 51a is in the range from approximately 6 mm to 12 mm and the length L of the horizontal part in the range from approximately 350 mm to 700 mm. and the maximum antenna cone results when the length D is about 8 mm and the length L is approximately 480 mm.

10 shows a comparison of the antenna gain of the antenna according to the invention with the known antenna, the antenna gain in dB being plotted on the vertical axis and the frequency in MHz being plotted on the horizontal axis. The antenna according to the invention selected for the comparison has a ferrite rod diameter of 20 mm, a ferrite rod _{length L f} of 75 mm, a length H of the second sections 51b of the folded conductor of 60 mm, a

Length D of the first sections 51a of the folded conductor of 8 mm and a length L of the first antenna part 10 of 480 mm. In Fig. 10 curve (a) represents the characteristic of the known standardized dipole antenna with a length of 1800 mm (equal to half the wavelength at 83 MHz), curve (b) the characteristic of the known standardized dipole antenna with a length of 1000 mm, the curve (c) the characteristic of the known standardized dipole antenna with a length of 600 mm, the curves (d ^), (dp) and (d,) the characteristics of the known ferrite antenna according to Fig. 1A and the curves (e «j) , (eg) and (e ~) represent the characteristics of the antenna according to the invention according to FIG. 2, where (d ^) and (e ^) for a resonance frequency of 76 MHz, (d ₂ ) and (e ₂ ) for a resonance frequency of 83 MHz and (d,) and (e,) apply for a resonance frequency of 90 MHz. As FIG. 10 shows, the antenna according to the invention has, with a horizontal length of approximately 480 mm, almost the same antenna gain as the conventional dipole antenna with a length which is equal to half the wavelength of 1800 mm. In the comparison according to FIG. 10, the antenna according to the invention was tuned to the frequencies 76 MHz, 83 MHz and 90 MHz by means of the adjustable capacitor 14b (see FIG. 2).

Fig. 11 shows the direction-dependent antenna gain of the invention Antenna in a horizontal plane in the form of a radiation diagram. As you can see, the radiation pattern has the shape of an "8". Therefore, if there are several transmitters, must the antenna can be aligned with the desired transmitter by rotating the first horizontal antenna part 10. the Tuning and / or rotating the antenna according to the invention is very easy because its horizontal length is very short compared to a known standardized A / 2 dipole antenna.

The antenna according to the invention is therefore suitable as an indoor antenna for receiving electromagnetic waves in the VHF / UHF range and has almost the same antenna gain as the known large Λ / 2 dipole antenna, despite the small dimensions of the

antenna according to the invention.

The antenna according to the invention is therefore very small in comparison to a known dipole antenna and still has a high antenna gain · Furthermore, rotating or aligning the antenna very easy. This results in an excellent indoor antenna for the VHF-UHF reception area.

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Claims (6)

Claims Has circular cross-section and with a resonant circuit coil and an output coil is provided, the resonant circuit coil being connected to an adjustable capacitor which together with the resonant circuit coil forms the resonant circuit, and the output coil with output connections is connected, characterized in that the antenna has a housing (20) that from the top of the housing (20) two substantially right-angled wings (10a, 10b) of a horizontal first antenna part (10) extend away in opposite directions that the wings (10a, 10b ) a folded elongated conductor with a plurality of first sections (51a) of length D parallel to the direction of the wings (10a, 10b) and a plurality of second sections (51b) of length H perpendicular to the direction of the first sections (51a) that the outer Ends (11) of the folded elongated conductor in the wings (10a, 10b) are free, that the ferrite rod (13) is arranged in the housing (20) ^; that the ferrite rod (13) has a coupling coil (12) which is connected to the inner ends of the folded elongated conductor in the wings (10a, 10b), that the first antenna part (10) with the two wings (10a, 10b) in the horizontal direction has a total length L in the range of about 350 mm to 700 mm, that the length of the first sections (51a) is about 6 mm to 12 mm and the length of the second sections (51b) is about 40 mm to 150 mm and that the ferrite rod (13) has a diameter of about 10 mm to 30 mm and a length of about 50 mm to 150 mm. 2. Antenna according to claim 1, characterized in that that the housing (20) has an upper cover (21), a lower cover (22) and side walls (23a, 23b), that a disc (24) is rotatably mounted on the upper cover (21) of the housing (20), that the horizontal dipole-like first antenna part (10) is arranged on the upper cover (21) of the housing (20) is, that the wings (10a, 10b) have a plastic plate (50) in which the folded elongated conductor is embedded is, that a first winding body (25) is attached to the disc (24) and the upper part of the ferrite rod (13) covers, that a second bobbin (26) covers the lower part of the ferrite rod (13), that the coupling coil (12) is wound on the first winding body (25),
that the resonant circuit coil (14a) on the second winding body (26) is wrapped, that a third winding body (27) is arranged on the second winding body (26), so that the third winding body (27) is vertically displaceable along the second winding body (26), that the output coil (15) on the third bobbin (27) is wound and that an adjusting device (28, 29) for moving the output coil (15) along the second winding body (26) is provided. 3. Antenna according to claim 1 or 2, characterized in that the folded elongate conductor lies in a substantially vertical plane. 4. Antenna according to claim 1 or Z _9, characterized in that the folded elongated conductor lies in a substantially horizontal plane. 5. Antenna according to claim 2, characterized in that the Adjusting device (28, 29) has a threaded hole (27c) in the third winding body (27) and one engaging in the threaded hole Has screw (28), so that the third winding body (27) along the second winding body (26) by rotation the screw (28) is displaceable. 6. Antenna according to claim 2, characterized in that the adjusting device (28, 29) has a vertical slot (26a) in the second bobbin and the third bobbin (27) has an inner projection (27d) which enters the slot slidably engages.